DE3842771A1 - HIGH PRESSURE DISCHARGE LAMP OF SMALL ELECTRICAL POWER AND METHOD FOR OPERATING - Google Patents

Description

The invention relates to a high-pressure discharge lamp small electrical power with those in the preamble of the main claim.

High-pressure discharge lamps, especially those with Metal halide filling, settle lately increasingly for the purpose of general lighting. But also for the headlights of motor vehicles Such lamps have already been proposed. For both Applications are power levels below 70 W, e.g. B. 35 W, completely sufficient. But it is unsatisfactory still the start-up time between the ignition and reaching the final luminous flux. It is at a conventionally operated lamp approx. 40 sec.

In DE-GM 86 23 908 it was therefore proposed that To externally heat the lamp when switched off so the fillers keep evaporated and on this way from a higher temperature and thus Pressure level based on a shortened start-up time of only about 8 seconds to reach. Apart from that for the additional heating required additional elek trical energy and the associated instal Lation effort is also such a shortened Start-up time for many applications still not satisfying.

The present invention is based on the object  the start-up time of the metal halide lamp increases even further shorten. On an external heating of the lamp should Consideration of the additional energy consumption and the measures for energy supply waived will.

These tasks are achieved through a combination of drawing features as indicated in the main claim solved. The main feature is the electronic one Ballast, with the help of a regulation of Starting current between the lamp ignition and the Reaching the final luminous flux in a range up to ten times the value of the nominal current is possible. The corresponding circuit arrangements are in the Patent applications with file number P 37 19 356 and P 37 19 357. The further form tion of the present invention is in the Unteran sayings. Through this mode of operation 90% luminous flux of a conventional metal halo genid lamp from originally approx. 30 sec to approx. 5 sec reduced. Another reduction to just approx. 1 sec for the 90% luminous flux is with a Combination of the remaining on the discharge vessel measures to be taken with regard to coating, Doping and the filling of the discharge vessel possible, with the control of the starting current up to the permissible upper limit of the electronic ballast device, namely up to approx. 10 times the nominal current done adequately. Compared to the conventional Operation of such a lamp means one Shortening the start-up time by a factor of 30. The high Overcurrent during the start-up phase heats the optimized Mass of the discharge tube quickly. The result  dene heat is then due to the doping of Discharge vessel material and the described different coatings in the discharge area reflected or absorbed by the barrel, so that the radiated heat reduced and heat loss mini be lubricated. The compared to conventional metal halo genidlampen additional heat gained in this way is fully used for the evaporation of the filling substances and thereby significantly reduces the start-up time Dimensions. The xenon in the discharge vessel causes a high Immediate light component immediately after the Ignition.

The invention is described below with the aid of three figures explained in more detail:

Fig. 1 shows a metal halide lamp having a radiation reflective coating in a schematic representation;

Fig. 2 shows the start-up curves a Betrie at a control handheld electronic ballast enclosed metal halide lamp without the reflective coating, without doping of the quartz glass and without xenon filling,

Fig. 3 shows the start-up curve of the luminous flux of a metal halide lamp operated with a controllable electronic ballast with a reflective coating and with xenon filling.

The metal-halide 1 of FIG. 1 is made of quartz glass and has a discharge up tube 2 with two on opposite sides of the discharge vessel 2 arranged inclusions in the form of a pinch 3. An electrode system is melted into each pinch 3 in a gas-tight manner, which consists of an electrode 4 made of tungsten arranged within the discharge vessel 2 , a sealing film 5 made of molybdenum embedded by the pinch 3 and a pinch 3 in the longitudinal axis of the lamp from current supply line 6 made of molybdenum. The current supply lines have an area of approximately 10 mm ² at the point of their smallest cross-section, in the present case the sealing foils 5 made of molybdenum. The electrodes 4 are in this exemplary embodiment from spherical electrodes with a spherical diameter of approximately 0.35 mm, which are located at the end of the tungsten wire with a diameter of approximately 0.18 mm.

In a preferred embodiment of a metal halide high pressure discharge lamp 1 with approximately 35 W power consumption, the discharge vessel 2 has an essentially elliptical shape with an outer diameter of approximately 5.5 mm and a length between the constrictions 7 of approximately 7 mm. The mass of this discharge vessel 2 is approximately 6 mg per watt of electrical power, in the present exemplary embodiment a 35 W lamp is approximately 0.2 g. In a volume of only 0.025 cm ³ , the discharge vessel 2 contains not only argon as the starting gas, but also mercury and the halides of sodium and preferably scandium or of sodium and a rare earth metal. At each constriction 7 , that is the transition area from the discharge vessel 2 to the squeeze 3 , a coating 8 made of silicon iron oxide is applied first and a further layer made of zirconium dioxide is applied over it. The angle α , which is formed by the lamp transverse axis and the connecting line between the center of the discharge space and the outer edge of the coating 8 on the discharge vessel 2 , lies before in the range between 50 ° and 55 °. The coating 8 thus pretty much covers the rooms behind the electrodes 4 and preferably heats them up. The transparent part of the discharge vessel 2 is also provided with a dichroic coating 9 of titanium dioxide and silicon dioxide which transmits visible radiation but reflects IR radiation and has a layer thickness of approximately 0.2 μm. The electrodes 4 are spherical on their mutually facing surface. A further measure, namely the doping of the quartz glass with a UV-absorbing agent, preferably titanium dioxide, in an amount of 0.02% by weight to 0.2% by weight was dispensed with in the present exemplary embodiment, as was the case with Filling the discharge vessel with xenon.

In FIGS. 2a and 2b, the start-up curves of a "naked" metal-halide 1 without any coating or doping of the quartz glass and without Xenon filling are shown. The lamp itself, however, was operated on an electronic African, the starting current regulating ballast according to the invention. The starting current of approx.2.6 A corresponds to approximately 6.5 times the nominal current of lamp 1 . As the diagram shows, the 30% -Lichtstrom Φ is sec at about 3.0, of 50% light power Φ at about 3.8 sec and the 90% -Lichtstrom Φ already at about 4.5 sec reached. The increase of the luminous flux Φ occurs steep and exceeds by about 5 sec the normal luminous flux Φ to about 120% in order then after about 15 sec to its nominal value set. The other measured parameters, such as color temperature T , operating voltage of the lamp U and its power consumption P , are also shown in the diagrams and do not require any further explanation.

The start-up curve of the luminous flux Φ in FIG. 3 is derived from a metal-halide discharge similar to FIG. 1, but without the coating 9, but with a container filled with xenon discharge vessel at a cold filling pressure of approximately 6 bar. The lamp was operated on the electronic ballast as in the previous example, the starting current being 3.3 A, which corresponds to approximately 8.5 times the nominal current. As can be clearly seen here, the increase in the luminous flux is steeper than in the example in FIG. 2a). The 90% luminous flux Φ is already reached here after approx. 1 sec. This extremely short start-up time can be reduced even further by applying the coatings 8 and 9 according to FIG. 1 and / or doping the quartz glass with TiO ₂ or CeO ₂ .

Claims (7)

1.High-pressure discharge lamp ( 1 ) of low electrical power with associated electronic ballast, in which the lamp has a discharge vessel ( 2 ) and a filling therein containing at least one noble gas, mercury and metal halides, and in the discharge vessel ( 2 ) at least two electrodes ( 4 ) are introduced in a gastight manner via current leads ( 6 ), characterized in that, in addition to features a) to c), at least one further of features d) to g) is present in combination.

• a) The electronic ballast contains a control device that sets the starting current of the lamp ( 1 ) to a value that is between five and ten times the value of the nominal current.
• b) The discharge vessel ( 2 ) contains at least the halides of sodium and scandium or of sodium and a metal of the rare earths as a filling.
• c) The mass of the discharge vessel ( 2 ) is in the range between 0.002 grams per watt and 0.1 grams per watt electrical power of the lamp.
• d) The discharge vessel contains xenon as the filling gas with a cold filling pressure of at least 3 bar.
• e) The discharge vessel ( 2 ) is at least partially provided with at least one agent which reflects or absorbs invisible radiation and transmits visible radiation.
• f) The shafts of the electrodes ( 4 ) have a maximum diameter of 0.3 mm.
• g) The facing part of the electrodes ( 4 ) is rounded.

2. High-pressure discharge lamp ( 1 ) according to claim 1, characterized in that the non-visible radiation reflecting and visible radiation transmitting means from a on the surface of the discharge vessel ( 2 ) applied dichroic coating ( 9 ) made of TiO ₂ or SiO ₂ and Si ₃ N ₄ exists. 3. High-pressure discharge lamp ( 1 ) according to claim 2, characterized in that the dichroic coating ( 9 ) has a thickness which is in the range from 0.1 µm to 1.5 µm. 4. High-pressure discharge lamp ( 1 ) according to claim 1 to 3, characterized in that the non-visible radiation-absorbing and visible radiation-transmitting means from a material of the discharge vessel ( 2 ) added doping made of TiO ₂ , CeO ₂ , TiO ₂ or BaMgAl ₂ O. ₃ exists. 5. High-pressure discharge lamp ( 1 ) according to claim 4 and 5, characterized in that the material of the discharge vessel ( 2 ) added doping has an amount ranging from 0.02 wt .-% to 0.2 wt .-% each Weight unit is. 6. High-pressure discharge lamp ( 1 ) according to claim 1 to 6, characterized in that the ends of the discharge vessel ( 2 ) are provided with a non-visible and visible radiation-reflecting coating ( 8 ) made of zirconium dioxide. 7. high-pressure discharge lamp ( 1 ) according to claim 7, characterized in that the ends of the discharge vessel ( 2 ) in addition to the coating ( 8 ) made of zirconium dioxide additionally have a coating of silicon iron oxide.